DE112018001453T5 - Stator and uniaxial progressing cavity pump - Google Patents

Abstract

The object of the present invention is to provide a long-life stator and a single-axis eccentric screw pump provided with the stator, which enable a comparatively long service life by preventing damage to the stator due to repeated attachment and removal to / from the single-axis eccentric screw pump. [Solution] A stator 20 includes an outer cylinder 30 and a stator main body 42 with flange-shaped sealing parts 46 and 47. The stator 20 includes fastening areas 24 and 25, to which the sealing parts 46 and 47 and the outer cylinder 30 are glued. The outer cylinder 30 and / or the sealing parts 46 and 47 have a fitting part which penetrates or is pressed in in the axial direction X and has a shape such that at least a part of the outer cylinder and / or the sealing parts is fitted into one another.

Description

Technical field

The present invention relates to a stator and a uniaxial eccentric screw pump.

State of the art

A single-axis eccentric screw pump for conveying fluid substances is conventionally known. The single-axis eccentric screw pump comprises a stator, which has an insertion hole with an internal thread, and an external thread rotor, which is inserted into the insertion hole of the stator and rotates eccentrically. In addition, most stators of uniaxial progressing cavity pumps have an outer cylinder made of a hard material such as metal and a stator main body which is formed by molding or casting an elastomer such as rubber or silicone and has the insertion hole with an internal thread. The outer cylinder and the stator main body are attached to an inner peripheral surface of the outer cylinder by a method such as gluing by means of adhesives or hot press joining.

The single-axis eccentric screw pump provided with the above-described stator is disclosed in Patent Document 1, explained below, filed by the assignee of the present invention. As in 16 shows a disclosed in Patent Document 1 stator 520 an outer cylinder 530 and a stator main body 542 on. At both ends of the stator main body 542 are sealing parts 546 and 547 intended. The seal parts 546 and 547 act as sealing elements and can prevent conveyed liquid into a gap between an inner peripheral surface 530a of the outer cylinder 530 and the stator main body 542 penetrates. In addition, in general, the outer cylinder 530 and the sealing parts 546 and 547 fixed by gluing with adhesives, hot-pressure joining etc. The stator 520 is kept in a state in which the sealing parts 546 and 547 between an end bolt 513 (a nozzle) and a pump housing 516 are trapped.

[Prior art document]

[Patent Document]

[Patent Document 1] JP 2004-360469A

[Brief Explanation of the Invention]

[Problem to be Solved by the Invention]

The stator disclosed in Patent Document 1 520 is elastically deformed, so that the sealing parts 546 and 547 radially expand due to influences of the clamping force, etc., of the end bolt 513 (the nozzle), etc., when they are attached to the single-axis eccentric screw pump. Thus, the relative positions between the sealing parts are different 546 and 547 and the outer cylinder ends 532 and 533 and it is to be feared that large stresses will act near the ends of the adhesive areas A.

More specifically, as in 17 etc. shown when attaching the stator 520 the sealing parts on the single-axis eccentric screw pump 546 and 547 between the elements (the end bolts, etc.), which are adjacent to the outer cylinder ends 532 and 533 are, and are from both sides in the axial direction of the stator 520 pressed. Here are the clamping force from both sides in the axial direction of the stator 520 the sealing parts 546 and 547 elastically deformed so that they extend radially outwards. In addition, if the stator 520 is removed from the pump, the sealing parts 546 and 547 from both sides in the axial direction of the stator 520 Relieved of the clamping force and deformed elastically so that they contract inwards in the radial directions.

When attaching and removing the stator 520 is repeated to / from the uniaxial eccentric screw pump, thus, the effect (change) of the voltage associated with the elastic deformation of the sealing parts 546 and 547 goes along, in the gluing areas A between the sealing parts 546 and 547 and the outer cylinder 530 repeated. Thus, loads of adhesive areas accumulate A between the sealing parts 546 and 547 and the outer cylinder 530 to, and there is a fear that the gluing areas A sooner or later they will be damaged by peeling, cracks, etc.

If there are parts of the adhesive areas A As described above, the problem arises that there is a gap between the sealing parts 546 and 547 (the stator main body 542 ) and the outer cylinder 530 forms. When the conveyed liquid enters such a gap, the damage spreads by peeling, cracks, etc. in the adhesive areas A off, and the life of the stator 520 can shorten.

In addition, the demand for small stators for conveying small quantities of fluids to be conveyed has recently increased. In the event of Of course, in such a small stator, the sealing parts and the outer cylinder are naturally downsized, and thus the adhesive surfaces between the sealing parts and the outer cylinder inevitably decrease, thereby deteriorating adhesiveness. Thus, in the case of the small stator, there is a fear that the possibility of occurrence of peeling, cracks, etc. in the above-described adhesive areas A further increases.

It is therefore an object of the present invention to provide a long-life stator and a stator-provided single-axis eccentric screw pump which allow a comparatively long period of use by preventing damage to the stator by repeated insertion and removal in / from the single-axis eccentric screw pump.

[Ways to solve the task]

In order to achieve the object explained above, a stator according to the present invention is a stator of a uniaxial eccentric screw pump, which is constructed in such a way that an externally threaded rotor is rotatably inserted into the internally threaded stator and an object to be conveyed is conveyed, by rotating the rotor eccentrically via a drive source. The stator includes a stator main body that is molded with elastomer, and has in its inner peripheral surface the insertion hole with internal thread that extends in the axial direction of the stator, and an outer cylinder that is attached to the outside of the stator main body. The stator main body has a flange-shaped sealing part at at least one end. The stator has a fastening area to which the sealing part and the outer cylinder are attached or glued. The outer cylinder and / or the sealing part have a fitting part or skeleton part which protrudes or is pressed in in the axial directions of the stator. The fitting part is shaped such that at least a part of the outer cylinder or the sealing part can be fitted into the other part. The fitting part and the fastening area are provided on at least one of the two ends of the stator and prevent deformation of at least part of the sealing part due to the stator being pressed in the axial direction.

The stator of the present invention has the fitting part projecting or pressed in the axial direction. Thus, the stator of the present invention is constructed so that in the fitting part, the sealing part and the outer cylinder are mounted to each other in the axial direction. Therefore, in the stator of the present invention, the mounting structure thus constructed in the fitting part effectively acts to restrict a radial elastic deformation of the sealing part, which is expected to accompany the expansion and contraction of the stator main body and so on. In this way, according to the present invention, a deviation of the relative positions between the seal member and the outer cylinder is prevented. In addition, the stator of the present invention thereby reduces damage to the portion (mounting portion) accompanied with the elastic deformation of the seal member to which the seal member and the outer cylinder are adhered. Therefore, the lifetime of the stator is prevented from being shortened.

Moreover, according to the present invention, the entire fitting part or a part thereof may constitute the fixing portion. As compared with a case where the attachment area is a flat surface like the adhesion area A of the conventional stator, the stator of the present invention expands the attachment area by widening the area of the part where the seal part and the outer cylinder are adjacent to each other.

It is desirable that the stator of the present invention has a wall surface that forms a side surface of the fitting part provided at the end of the outer cylinder, and that the wall surface restricts the deformation in at least a part of the sealing part in a direction corresponding to the axial direction of the seal Stators cuts.

The stator of the present invention comprises the wall surface forming the side surface of the fitting part provided at the end of the outer cylinder. In the stator of the present invention, the wall surface can also effectively function to restrict the deformation of at least the part of the seal member in the direction that intersects the axial direction of the stator (eg, the radial direction when the stator has a cylindrical shape Hereinafter, a "direction intersecting the axial direction of the stator" may be referred to as a "radial direction" unless otherwise specified). Therefore, the stator of the present invention reduces damage, etc., of the portion where the seal member and the outer cylinder adhere (attachment portion), which accompanies the elastic deformation of the seal member.

It is desirable that the stator of the present invention have a wall surface that forms a side surface of the fitting part provided at the end of the outer cylinder, and that all or part of the wall surface is formed so that it is wholly or partly to the contour of the Circumferential surface of the sealing part fits.

The stator of the present invention includes the wall surface that forms the side surface of the fitting provided at the end of the outer cylinder. Also in the stator of the present invention, all or part of the wall surface is formed to match all or part of the contour of the sealing part, and thus the elastic deformation of the sealing part is restricted in the direction in which it is the axial direction of the stator cuts. Therefore, according to the present invention, the damage, etc., associated with the elastic deformation of the seal member is reduced in the area (attachment area) to which the seal member and the outer cylinder stick.

It is desirable that the stator of the present invention has a wall surface that forms a side surface of the fitting part provided at the end of the outer cylinder, and that the entire wall surface or a part thereof is disposed so as to face at least a part of the peripheral surface of the seal part.

According to the structure, the wall surface is arranged such that it faces the outside (that is, the peripheral surface) of the sealing part. Thus, the stator of the present invention effectively limits the radially outward elastic deformation of the sealing member. Specifically, the radially outer portion of the seal member deforms a lot when it is pressed in the axial direction, and it is subjected to great tension. With the above structure, the stator of the present invention limits the radially outward elastic deformation of the seal member in the part adjacent to the peripheral surface of the seal member where the large stress is expected to occur.

Here, the conventional stator is constructed so as to provide the region in which the seal member formed in a substantially flat shape is connected to a substantially flat end surface (a connection portion) provided at the end of the outer cylinder (FIG. please refer 17 ). However, such a structure may cause damage to the bonding area (eg, peeling of adhesives, etc.) by nails, thin instruments, etc. penetrating between the seal portion and the outer cylinder. Therefore, it is desirable to take measures to prevent other elements, such as the thin instruments, from entering the part in which the seal member and the outer cylinder abut each other.

In view of the problems described above, it is desirable that the stator of the present invention include a wall surface forming a side surface of the fitting provided at the end of the outer cylinder, and it is desirable that all or part of the wall surface be arranged so that it surrounds the peripheral surface of the sealing part.

According to the structure, in the part where the wall surface is arranged to surround the sealing part, nails, thin instruments, etc. are prevented from entering between the sealing part and the outer cylinder. Thus, the possibility of the occurrence of an unexpected defect such as peeling, cracking, etc. in the connecting part between the sealing part and the outer cylinder is reduced.

Furthermore, when constructed as explained above, the radial elastic deformation of the sealing part is limited in the part in which the wall surface is arranged to surround the sealing part. Moreover, if it is constructed as explained above, it becomes possible to glue the periphery of the seal member and the wall surface, and the area (attachment area) to which the seal member and the outer cylinder are adhered is further enlarged. Thus, the sealing part and the outer cylinder stick to each other more firmly.

In addition, structuring of the stator of the present invention as explained above is advantageous in a case of casting the stator main body using a die. More specifically, in molding the stator main body using the mold, a mold removing process is performed. At this time, if the mold is removed while the seal member adheres to the mold, the mold will pull on the seal member, and peeling, etc. may occur in the mounting portion. However, the stator of the present invention is constructed with the part where the wall surface surrounds the sealing member as described above. Thus, according to the structure, the contact area between the seal forming part and the mold becomes smaller around the area of the part having the wall surface around the peripheral surface of the seal part. Therefore, according to the present invention, even in one case, the stator is provided in which the stator main body is molded with the mold that can be manufactured without peeling, etc., occurring in the mounting area.

The stator of the present invention is desirably constructed to include a wall surface that forms a side surface of the fitting provided at the end of the outer cylinder and a receiving area that is constructed within the wall surface. It is desirable that all or part of the wall surface is arranged to surround the peripheral surface of the sealing part, and it is desirable that the sealing part has a part contained in the Receiving area is received, and a part that protrudes from the receiving area in the axial direction of the stator.

According to the construction, by inserting the part of the sealing member (hereinafter also referred to as "projecting member") projecting from the receiving portion in the axial direction of the stator to another member constituting the object to be connected, sufficient sealing performance is provided secured connecting object. More specifically, when the stator of the present invention is mounted on a single-axis eccentric screw pump, it can effectively function in ensuring sealing performance by moving the protruding part of the sealing member toward the other member that is the object to be connected (e.g. which is referred to as Endbolzen, etc.) is arranged.

Similar to the structure described above, in the stator of the present invention, there is the part in which the wall surface is arranged to surround the sealing part. In this way, nails, thin instruments, etc. are prevented from getting between the seal member and the outer cylinder, and the occurrence of an unexpected defect, etc., associated with the disconnection, etc., of the joint member of the seal member and the outer cylinder is reduced.

Providing the wall surface described above further limits the radial elastic deformation of the sealing part in the part in which the wall surface is arranged. In addition, because the wall surface sticks between the sealing part and the outer cylinder, the wall surface can be used to expand the fastening area of the sealing part and the outer cylinder. Therefore, according to the present invention, the seal member and the outer cylinder stick to each other more firmly.

In addition, the present invention is effective when producing a high-quality stator in a case where the stator main body is molded in the mold. In detail, in the stator of the present invention, there is the part in which the wall surface is arranged to surround the seal part, and the contact area between the seal forming part and the mold becomes smaller around the surface. Therefore, according to the present invention, even in a case where the stator main body is molded with the mold, the high-quality stator can be provided without peeling, etc. in the mounting area.

As for the stator of the present invention, the fitting part provided at the end of the outer cylinder may be the outer cylinder end having a step in the axial direction of the stator.

According to the structure, the radial elastic deformation of the sealing part is limited.

As for the stator of the present invention, the fitting part provided at the end of the outer cylinder may be formed with one or both of a concave portion formed in a concave shape in the axial direction of the stator and a convex portion formed in a convex shape is.

According to the construction, by the convex part and the concave part constituting the fitting part, the fitting structure is provided to the seal part and the outer cylinder end part.

As for the stator of the present invention, it is desirable that the sealing part and the outer cylinder are fixed by gluing with adhesives or by hot pressing.

In the stator of the present invention, the radial elastic deformation of the seal member is limited by having the above-described structure in which the seal member and the outer cylinder are fitted to each other in the axial direction in the fitting part. Thus, the stator of the present invention can stably be used without excessive force being applied to the bonded part or the hot-press-fitted part between the seal member and the outer cylinder in a situation where the radial elastic deformation of the seal member and the like may occur.

A single-axis eccentric screw pump of the present invention comprises the above-described stator of the present invention.

According to the present invention, the uniaxial eccentric screw pump provided with the durable stator can be provided.

Effect of the Invention

According to the present invention, the durable stator and the uniaxial eccentric screw pump provided with this stator, which enable the comparatively longer service life, can be provided by preventing the stator from being damaged due to repeated attachment and removal to / from the uniaxial eccentric screw pump.

list of figures

• 1 10 is a cross-sectional view of a single-axis progressing cavity pump having a stator according to a first embodiment of the present invention.
• 2 FIG. 12 illustrates a stator according to the first embodiment of the present invention, wherein (a) is a front view and (FIG. b ) is a sectional view from the side.
• 3 shows a substantial part of the outer cylinder of the stator of 2 , in which ( a ) a perspective view and ( b ) is a sectional view from the side.
• 4 FIG. 12 is a sectional view showing an essential part of the stator of FIG 2 look light.
• 5 is a sectional view showing the stator of 2 illustrated when it is released from a mold in a casting process.
• 6 Fig. 11 is a conceptual view illustrating a state in which the stator is made 2 is attached to the uniaxial progressing cavity pump.
• 7 Fig. 10 is a cross sectional view in which an essential part of the 6 is enlarged.
• 8th shows a stator according to a second embodiment of the present invention, wherein ( a ) a front view and ( b ) is a sectional view from the side.
• 9 shows a substantial part of the outer cylinder of the stator of 8th , in which ( a ) a perspective view and ( b ) is a sectional view from the side.
• 10 FIG. 12 is a cross sectional view showing an essential part of the stator of FIG 8th represents.
• 11 FIG. 10 is a cross-sectional view illustrating an essential part of a stator according to a third embodiment of the present invention. FIG.
• 12 shows an example of a wall surface of the stator of the present invention, wherein ( a ) is a wall surface which is substantially perpendicular to a bottom surface, ( b ) is a wall surface forming an obtuse angle to the bottom surface, and ( c ) is an example of a wall surface which forms an acute angle to the bottom surface.
• 13 shows modifications of the fitting part of the stator of the present invention, wherein ( a-1 ) is a front view of the stator having a fitting part that is a concave part of a circumferential groove, a-2 ) is a sectional view showing an essential part of the stator of ( a-1 ) represents ( b-1 ) is a front view of the stator provided with a fitting part which is an annular convex part, and ( b-2 ) is a sectional view showing an essential part of the stator of ( b-1 ) represents.
• 14 illustrates modifications of the fitting part of the stator of the present invention, wherein ( a ) is a fitting part with several convex parts, ( b ) is a fitting part with a concave part and a convex part, ( c ) is a fitting part with several convex parts, and ( d ) is a fitting in which two wall surfaces form an acute angle.
• 15 shows modifications of the fitting part of the stator of the present invention, wherein (a) is a fitting part having a shape in which the ring shape is partially divided, ( b ) is a fitting part with a polygonal shape and ( c ) is an example in which an oval fitting part for the stator is provided with an oval outer cylinder.
• 16 Fig. 11 is a conceptual view illustrating a state in which a conventional stator is attached to the uniaxial progressing cavity pump.
• 17 FIG. 12 is a sectional view showing an essential part of the stator of FIG 16 look light.
• 18 is a sectional view showing the stator of 16 represents when it is released from a mold in a molding process.

[Modes for Carrying Out the Invention]

The following is a single-axis eccentric screw pump 10 and a stator 20 according to an embodiment of the present invention with reference to the figures described in detail. Note that in the following the overall structure before the description of the stator 20 although the feature of the single-axis eccentric screw pump 10 in the stator 20 located.

«Overall design of the single-axis eccentric screw pump 10»

The single-axis eccentric screw pump 10 is a so-called rotary positive displacement pump. As in 1 is shown, is the single-axis eccentric screw pump 10 designed so that a rotor 50 , the stator 20 and a power transmission mechanism 60 etc. in a pump housing 16 and a stator housing 18 are housed. The single-axis eccentric screw pump 10 is constructed so that the power transmission mechanism 60 etc. in the pump housing 16 is housed, during the stator 20 and the rotor 50 etc. in the stator housing 18 are housed.

The pump housing 16 is a cylindrical member made of metal, and has a stator attachment part in the longitudinal direction on one end side 16a on. In addition, the stator housing 18 on a tail pipe 13 mounted on one end side in the longitudinal direction, with a first opening part 14a Provided. In addition, a second opening part 14b on the outer peripheral part of the pump housing 16 intended. The second opening part 14b stands with an interior of the pump housing 16 in a central part in the longitudinal direction of the pump housing 16 in connection.

The first opening part 14a and the second opening part 14b are parts, each as the intake and exhaust port of the single-axis eccentric screw pump 10 serve. The single-axis eccentric screw pump 10 causes the first opening part 14a as an outlet opening and the second opening part 14b acts as a suction port by the rotor 50 turns in the positive direction. Alternatively, it leaves the first opening part 14a as the suction opening and the second opening part 14b work as a discharge opening by the rotor 50 for maintenance, etc. is rotated in the opposite direction to the interior, etc. of the pump housing 16 to clean.

The stator 20 is in the stator housing 18 housed in a state in which one of its ends on the end bolts 13 adjacent and the other end into the stator mounting part 16a of the pump housing 16 is fitted.

The stator 20 is an element that appears in a substantially cylindrical shape. The stator 20 includes a cylindrical outer cylinder 30 made of metal and a stator main body 42 made of an elastic material such as rubber or an elastomer such as resin. The stator 20 is constructed such that the stator main body 42 in the outer cylinder 30 lies.

The stator main body 42 takes a cylindrical part (described below) 44 in the outer cylinder 30 on. The outer diameter of the stator main body 42 corresponds essentially to the inner diameter of the outer cylinder 30 , Thus, the stator main body is 42 in a state in which its outer peripheral surface is substantially close to an inner circumferential surface 30a of the outer cylinder 30 and is integrally formed by fasteners such as adhesives. As in 1 is shown, is an insertion hole 48 in the stator main body 42 formed, and an inner peripheral surface 42a is brought into a female thread form with n slots and a single turn or multiple turns. In this embodiment, the inner circumferential surface comprises 42a the insertion hole 48 two grooves and multiple turns or screw threads in a female thread form. Note that the structure of the stator 20 will be described later in detail.

The rotor 50 is a metal shaft body and has an external thread with n-1 grooves and one turn or multiple turns. In this embodiment, the rotor 50 in an eccentric external thread form with a groove. The rotor 50 has at each position in the longitudinal direction of a substantially perfectly circular cross-sectional shape. The rotor 50 is in the insertion hole 48 used in the stator main body described above 42 is formed, and is within the insertion hole 48 rotatable eccentrically.

If the rotor 50 in the stator 20 is inserted, an outer peripheral wall 50a of the rotor 50 and the inner peripheral surface 42a of the stator main body 42 in a state in which they are close to each other on their tangent lines, and a fluid delivery path 52 (Cavity) is between the inner peripheral surface 42a of the stator main body 42 and the outer peripheral wall 50a of the rotor 50 educated. The fluid delivery path 52 extends spirally in the longitudinal direction of the stator 20 and the rotor 50 ,

If the rotor 50 in the insertion hole 48 of the stator main body 42 is rotated, the fluid conveying path moves 52 in the longitudinal direction of the stator 20 forward while standing in the stator main body 42 rotates. If the rotor 50 is rotated, thus fluid from one end side of the stator 20 in the fluid conveying path 52 sucked in a state in which the fluid inside the Fluidförderwegs 52 is trapped, becomes the other end side of the stator 20 transported and is on the other end side of the stator 20 issued.

The power transmission mechanism 60 serves a driving force from a drive source 58 on the rotor described above 50 transfer. The power transmission mechanism 60 includes a power transmission part 64 and an eccentrically rotating part 62 , The power transmission part 64 is in the longitudinal direction of the pump housing 16 provided on one end side. In addition, the eccentrically rotating part 62 on an intermediate part 54 intended. The eccentrically rotating part 62 is a part of the power transmission part 64 with the rotor 50 power transmission connects. The eccentrically rotating part 62 has a clutch shaft 63 on, which consists of a conventionally known coupling rod, a threaded rod, etc. Thus, the eccentrically rotating part 62 the rotational driving force on the rotor 50 transferred that through Actuation of the drive source 58 is generated to the rotor 50 to turn eccentrically.

«Construction of the stator 20»

The following is the stator 20 of the present invention described in detail. As in 2 B) is shown, the stator comprises 20 the present invention, the outer cylinder 30 and the stator main body 42 ,

Note that in the description below, the axial direction of the stator 20 (Longitudinal direction) are referred to as "axial direction X". It also becomes a state in which the stator 20 in the axial direction X from the end fitting side 13 is seen as described as "the front view".

The stator 20 is constructed so that the outer cylinder 30 externally on the stator main body 42 is appropriate. The stator 20 For example, by assembling the outer cylinder 30 and the stator main body 42 with a technique such as pouring molding material of the stator main body 42 in the outer cylinder 30 made, to which it is glued. Note that the molding of the stator main body 42 will be explained later.

As in 2 B) shown, has the stator 20 stator ends 22 and 23 at both ends in the axial direction X , The stator ends 22 and 23 each have attachment areas 24 respectively. 25 on. In addition, the outer cylinder has 30 Outer cylinder ends 32 and 33 at both ends in the axial direction X , The stator main body 42 has flange-shaped sealing parts 46 and 47 on both sides in the longitudinal direction. The stator 20 has the attachment areas 24 and 25 each in a contact part between the outer cylinder ends 32 and 33 and the sealing parts 46 respectively. 47 on. The stator 20 is constructed so that the outer cylinder ends 32 and 33 in the attachment areas 24 respectively. 25 at the sealing parts 46 and 47 are fixed by adhesives and the like.

In addition, the stator points 20 fitting portions 26 and 27 on. The fitting parts 26 and 27 are concave parts, each at both ends of the outer cylinder ends 32 and 33 are formed. The stator 20 is constructed such that the sealing parts 46 and 47 in the axial direction X into the outer cylinder ends 32 and 33 are introduced (or penetrate). In the stator 20 This embodiment is the Einpassteil 26 and the attachment area 24 at the end of the stator 22 intended. In addition, in the stator 20 the fitting part 27 and the attachment area 25 at the end of the stator 23 intended.

As in 2 B) is shown is the outer cylinder 30 a hollow cylindrical element made of metal. As described above, the outer cylinder is 30 outside of the stator main body 42 appropriate. Note that for the material of the outer cylinder 30 a hard material can be chosen appropriately. For example, you can use the material of the outer cylinder 30 choose a material such as resin or plastic.

The outer cylinder 30 This embodiment is a cylindrical body with a substantially circular cross section. As in 3 (b) is shown, the outer cylinder 30 a through hole 40 on that in the axial direction X penetrates. The stator main body 42 is in the outer cylinder 30 added to be substantially close to the inner peripheral surface 30a of the through hole 40 to rest.

Note that the outer cylinder 30 Although it has a substantially cylindrical appearance, it may have any kind of shape as long as it conforms to the shape of the stator main body 42 fits. For example, the outer cylinder 30 a substantially oval cross-sectional shape (see 15 (c) ) or have a substantially triangular cross-sectional shape.

As in 2 B) are shown in the outer cylinder 30 the fitting parts 26 and 27 (concave parts) at the outer cylinder ends 32 and 33 intended. The fitting part 26 is at the end of the outer cylinder 32 on the end fitting side 13 provided, and the fitting part 27 is at the end of the outer cylinder 33 on the side of the pump housing 16 intended. Because in this embodiment the sealing parts 46 and 47 are essentially circular in the front view, the fitting parts 26 and 27 formed so concave that they are essentially circular in front view. Note that the fittings 26 and 27 are structured similarly. Thus, in the following description, the fitting part 26 Described in detail while referring to a description of the fitting 27 is waived.

As in 3 (a) shown is the fitting part 26 (concave part) formed as a substantially circular recess that in the axial direction X from an end face 32a of the outer cylinder end 32 is depressed. As in 2 (a) shown, the fitting part 26 an essentially circular contour with a diameter D1 on, in the front view the entire outer circumference of the outer cylinder 30 equivalent. Thus, the fitting part 26 made in size and shape in which the sealing part 46 of the stator main body 42 can be fitted without a significant gap. In other words, the fitting part 26 intended to be in axially X wider than the end face 32a of the outer cylinder end 32 in the sealing part 46 of the stator main body 42 protrudes (passes), and part of the sealing part 46 is in the outer cylinder 30 fitted.

As in the 3 (a) and (b) is illustrated, the concave part forms the fitting part 26 forms a step in the outer cylinder end 32 , In particular, the fitting part 26 a floor area 34b on that from the end face 32a in the axial direction X by a distance L1 is indented, and is brought into a shape in which the step between the end surface 32a and the floor area 34b is trained.

As in the 3 (a) and (b) shows, the fitting part 26 a wall surface 34a on, which forms a side surface (inner peripheral surface). In particular, the Einpassteil 26 the wall surface 34a on, extending in the axial direction X between the end surface 32a and the floor area 34b expands. The wall surface 34a is brought into the shape that is curved by so-called rounding and the like. The floor area 34b is an area that is essentially parallel to the end face 32a is and is designed to be off the wall surface 34a is surrounded. The fitting part 26 includes a receiving area 36 in which the sealing part 46 in the wall surface 34a can be accommodated.

As in 2 B) is shown, the stator main body 42 the cylindrical element on which the cylindrical part 44 and the sealing parts 46 and 47 are integrally formed. The insertion hole 48 with the female thread shape described above is in the stator main body 42 designed so that it is in the axial direction X extends. The stator main body 42 is molded from a suitable material, for example a rubber such as nitrile rubber, ethylene-propylene rubber or fluoride rubber or an elastomer such as silicone. In addition, the stator main body 42 on the outer cylinder 30 for example, by a molding technique for molding molding material into the sticky outer cylinder 30 attached.

The cylindrical part 44 has tapered parts where the diameter near both ends gradually increases. The sealing parts 46 and 47 are on both sides of the cylindrical part 44 trained and manufactured in flange form. In addition, as in 2 (a) shown, the sealing parts 46 and 47 in the front view the substantially circular shape.

Note that the seal part 46 and the sealing part 47 have a similar structure. Therefore, in the following description, the seal member 46 exactly described and a description of the sealing part 47 omitted.

As in 2 B) is shown is the sealing part 46 the flange-shaped part that at the end of the stator main body 42 is expanded radially outwards. As in 2 (a) is shown is the sealing part 46 The front view is designed to have a substantially circular shape with a diameter D2 having. The diameter D2 of the sealing part 46 essentially agrees with the diameter D1 of the fitting 26 match. Furthermore, as in 4 shown, the sealing part 46 the thickness of a distance L2 in the axial direction X ,

As in 4 is shown, the sealing part 46 an adhesive surface 46a , a sealing surface 46b and a peripheral surface 46c on. The adhesive surface 46a is an area that is at the end face 32a of the outer cylinder 30 sticks and to the end face 32a of the outer cylinder 30 adjacent (opposite) is. In addition, the sealing surface 46b a surface that is at an outer end of the stator main body 42 is trained. The adhesive surface 46a and the sealing surface 46b are designed to form a substantially flat surface. In addition, the peripheral surface 46c formed as a curved surface leading to the curved shape of the wall surface 34a fits. In particular, the peripheral surface 46c formed so that it is the curved surface, in the axial direction X is substantially radially arched towards the middle.

Next, an outline of a procedure for forming the stator main body 42 in the outer cylinder 30 this embodiment and a damage control of the sealing parts 46 and 47 when molding the stator main body 42 described.

If the stator main body 42 to the outer cylinder 30 is molded or cast, adhesives are first on the inner circumferential surface 30a and the outer cylinder ends 32 and 33 of the outer cylinder 30 applied. Next is the outer cylinder 30 in a certain form M inserted, and a core with an internal thread (not shown) is in the outer cylinder 30 arranged. Next, elastomer is poured in, which is the material for molding the stator main body 42 is used. Thus, the stator main body 42 with the internal thread insertion hole 48 and the sealing parts 46 and 47 molded in a state where it is on the outer cylinder 30 sticks.

As in 5 is shown after the end of the procedure described above, the form M from the stator 20 removed and then the core (not shown) removed. While removing the mold M has a pulling force (see arrow in 5 ) in a separation direction from the mold M on the sealing parts 46 and 47 that are cast products by looking from the mold M to be pulled.

Here is the stator 20 This embodiment is shaped so that it is in a state in which a part of the sealing part 46 in the fitting part 26 of the outer cylinder 30 is fitted. More specifically, the sealing part gets 46 in a state in which a part of the peripheral surface 46c in the axial direction X in the recording area 36 is fitted. In addition, parts are other than the part that is in the shooting area 36 of the sealing part 46 is recorded, formed in a state in which it is in the axial direction X from the recording area 36 protrude outwards. In other words, the stator main body is in the process of casting 42 the part of the peripheral surface 46c of the sealing part 46 arranged adjacent to the wall surface 34a opposite, and other parts become parts that touch the M shape.

As in 4 etc. is also shown in the stator 20 the sealing part 46 on the outer cylinder 30 by applying adhesives etc. not only to the floor surface 34b that propagates in the directions that the axial direction X cut (radial directions), but also on the wall surface 34a attached, which is designed so that it is in the axial direction X runs. Thus, the stator 20 have a larger adhesive surface (mounting surface) than when the outer cylinder 530 and the stator main body 542 like the conventional stator 520 are attached only to the surface (end surface) which spreads radially. Furthermore, the wall surface 34a Also, a surface that removes the removal direction from the mold M cuts. Thus, the wall surface 34a in comparison to the floor area 34b hardly absorb the influence of tension when removing from the mold M acts. Therefore, in the stator 20 the force (tensile force) due to the removal of the mold M is caused on the wall surface 34a and the floor area 34b distributed and recorded by both. In addition, in the stator 20 the area that the form M when casting touches the area of the part smaller, since the part of the peripheral surface 46c of the sealing part 46 in the recording area 36 is included. Due to these effects, the problem can be reduced that the sealing part 46 under the influence of force when removing from the mold M when casting the stator 20 unexpectedly from the outer cylinder 30 is disconnected.

Note that in the stator 20 this embodiment of the stator main body 42 by casting the molding material of the stator main body 42 into the mold M is formed, which is the outer cylinder 30 but the stator of the present invention is not limited to this production.

For example, the stator of the present invention may include the stator main body 42 on the outer cylinder 30 fix it by the adhesion on the outer cylinder 30 is used, the mold material, such. B. elastomer, even without the intermediate material such. As adhesives to use. In addition, the stator of the present invention, the outer cylinder 30 made of hard material of resin and the outer cylinder 30 and the stator main body 42 fix by pressure under heat, etc. Alternatively, the stator of the present invention may be manufactured by mounting the stator main body 42 and the outer cylinder 30 prepared previously cast with the cast stator main body 42 integral by gluing with adhesives or by hot pressing by means of heating on the outer cylinder 30 is attached. Thus, the stator of the present invention may optionally be on the outer cylinder 30 or on the stator main body 42 be attached.

Next, a deformation control of the seal parts 46 and 47 when attaching and removing the stator 20 on the single-axis eccentric screw pump 10 described.

As in 6 (a) is shown when attaching the stator 20 on the uniaxial progressing cavity pump 10 in the axial direction X from both sides on the sealing parts 46 and 47 pressed. More specifically, when attaching the stator 20 on the uniaxial progressing cavity pump 10 the sealing part 46 from both sides in the axial direction X pressed by placing it between the outer cylinder end 32 and the end connector 13 is pinched. In addition, the sealing part 47 from both sides in the axial direction X pressed by placing it between the outer cylinder end 33 and the pump housing 16 is pinched. The sealing parts thus incline 46 and 47 to deform elastically so that they expand radially outwards (see 7 ).

Here is the sealing part 46 This embodiment is cast in a state in which the part of the peripheral surface 46c in the axial direction X from the wall surface 34a is surrounded. That is, the peripheral surface 46c of the sealing part 46 gets into a state in which it is from the wall surface 34a is surrounded. As in 7 is shown touches the part of the sealing part 46 from the wall surface 34a is surrounded (part that in the recording area 36 is included), the wall surface 34a , and its radially outward elastic deformation is limited (see arrow d1 in 7 ). It also touches on the sealing part 47 the part of the sealing part 47 from the wall surface 35a (part that is in a recording area 37 is included), the wall surface 35a , and its radially outward elastic deformation is limited (not shown).

Thus, when installing the single-axis eccentric screw pump 10 on the stator 20 at least the radial elastic deformation of the parts of the sealing parts 46 and 47 controlled that in the recording areas 36 and 37 are included, even if the clamping forces in the axial direction X from both sides on the sealing parts 46 and 47 act. Thus, shear forces in the radial directions of the stator 20 be prevented on the attachment areas 24 and 25 Act. Because the sealing parts 46 and 47 are attached in a state in which their radial elastic deformations are controlled, furthermore, elastic deformations occur for contracting the sealing parts 46 and 47 in the radial direction hardly when the stator 20 disassembled from the uniaxial progressing cavity pump. Even if that on the seal parts 46 and 47 when attaching and removing to / from the uniaxial progressing cavity pump 10 acting clamping force for the stator 20 fluctuates, there is hardly any radial deformation of the sealing parts 46 and 47 to take place. Therefore occurs at the stator 20 a defect such as B. the detachment of the sealing parts 46 and 47 from the outer cylinder ends 32 and 33 , not without further ado.

Next is a function of the sealing parts 46 and 47 as sealing elements in the stator 20 described in this embodiment.

As in the 2 and 4 explained applies to the stator 20 that the parts of the seal parts 46 and 47 in the reception areas 36 and 37 are housed while other parts in the axial direction X from the reception areas 36 and 37 protrude outward (referred to as "protruding parts" in the description of this embodiment below). In addition, as in 6 shown in the state in which the stator 20 on the uniaxial progressing cavity pump 10 is attached, the protruding part of the sealing part 46 fitted into the concave part that in the end connector 13 is trained. The protruding part of the sealing part 47 is fitted in the concave part, that in the pump housing 16 is trained. In addition, the radially outward elastic deformations of the parts of the sealing parts 46 and 47 that in the recording areas 36 and 37 are housed through the wall surfaces 34a and 35a (see arrow d1 in 7 ) is restricted, while the protruding parts are permitted to a certain extent to the radially outward elastic deformations (see arrow d2 in 7 ). So if the compressive forces from both sides in the axial direction X on the sealing parts 46 and 47 suitable for fastening the stator 20 on the uniaxial progressing cavity pump 10 act, the protruding parts of the sealing parts 46 and 47 elastically deformed radially outwards. Thus, the gaps between the end connector 13 and the pump housing 16 on the one hand and the outer cylinder 30 on the other hand by the protruding parts of the sealing parts 46 and 47 filled, so that leakage of liquid or gas is prevented. That is, the protruding parts of the seal parts 46 and 47 act as the sealing elements.

As in 4 etc. are shown for the stator 20 the adhesive surfaces 46a and 47a of the sealing parts 46 and 47 and the floor surfaces 34b and 35b the outer cylinder ends 32 and 33 essentially all formed as flat surfaces. Furthermore, are in the stator 20 the wall surfaces 34a and 35a provided so that the adhesive surfaces 46a and 47a and the floor surfaces 34b and 35b each surrounded by radially outside. Even if a thin instrument and the like are near the sealing parts 46 and 47 used when attaching and detaching the stator, etc. 20 takes place, or even if a worker seals the parts 46 and 47 holding in hand are the wall surfaces 34a and 35a no obstacles, and the instrument, nails, etc. described above do not penetrate between the adhesive surfaces 46a and 47a and the floor surfaces 34b and 35b on. Thus, the defect, such as the detachment in the fastening areas 24 and 25 be prevented by pinching the instrument etc. between the adhesive surfaces 46a and 47a and the floor surfaces 34b respectively. 35b is caused.

"Second embodiment"

Then a stator 120 according to a second embodiment of the present invention. Note that in the following description of the stator 120 structures similar to those in the stator 20 be described with the same reference numerals as in the description of the stator 20 assigned to omit a detailed description thereof.

As in 8th has shown the stator 120 an outer cylinder 130 and a stator main body 142 , The stator main body 142 is in one piece with flange-shaped sealing parts 146 and 147 on both sides of the cylindrical part 44 educated. It is also in the stator main body 142 an insertion hole 48 trained with internal thread. Regarding the stator 120 are the outer cylinder 130 and the stator main body 142 by the technique of casting the molding material of the stator main body 142 in the outer cylinder 130 , to which adhesives adhere, similar to the stator 20 formed in one piece of the first embodiment.

As in 8 (b) shown, the stator 120 stator ends 122 and 123 at both ends in the axial direction X of the outer cylinder 130 , fixing areas 124 and 125 are at the stator ends 122 and 123 educated. Regarding the stator 120 are the attachment areas 124 and 125 at the stator ends 122 respectively. 123 educated. In addition, the outer cylinder has 130 Outer cylinder ends 132 and 133 at both ends in the axial direction X , The stator main body 142 includes flange-shaped sealing parts 146 and 147 on both sides in the longitudinal direction. The stator 120 is through the outer cylinder ends 132 and 133 formed and the sealing parts 146 and 147 are in each case by adhesives and the like in the fastening areas 124 respectively. 125 attached.

In addition, the stator points 120 fitting portions 126 and 127 on. The fitting parts 126 and 127 are convex parts, each in the outer cylinder ends 132 respectively. 133 are formed. The stator 120 is constructed so that the fitting parts 126 and 127 which are in the outer cylinder ends 132 and 133 are provided, are fitted into the concave parts, in the sealing parts 146 and 147 in the axial direction X are formed (or protrude).

As in 8 (b) is shown is the Einpassteil 126 so provided that it from the outer cylinder end 132 to the end neck 13 protrudes. In addition, the Einpassteil 127 so provided that it from the outer cylinder end 133 to the pump housing 16 protrudes. Note that the fitting part 126 and the fitting part 127 are constructed similarly. Thus, the Einpassteil 126 in the following description of this embodiment, and a detailed description of the fitting 127 is omitted.

As described above, the outer cylinder has 130 the fitting part (convex section) 126 on. The fitting part 126 this embodiment is a convex portion in the outer cylinder end 132 is trained. In addition, forms the Einpassteil 126 in the outer cylinder end 132 a step in the axial direction X to the end neck 13 protrudes.

As in the 9 (a) and (b) illustrates the fitting part 126 this embodiment is brought into a shape which is annular from an end surface 132a of the outer cylinder end 132 protrudes. The fitting part 126 more precisely, it is provided at a position away from a peripheral edge 132b the endface 132a offset radially inward. In addition, the Einpassteil 126 designed so that it reaches the peripheral edge 132b the endface 132a fits.

As in the 9 (a) and (b) has the mating part 126 an inner wall surface 134a on the inner peripheral side and an outer wall surface 134b on the outer peripheral side as the side surfaces (peripheral surfaces) forming the convex shapes. The inner wall surface 134a and the outer wall surface 134b are formed as side surfaces (peripheral surfaces), which are substantially in the axial direction X run. In addition, has the Einpassteil 126 an outstanding endface 134c between the inner wall surface 134a and the outer wall surface 134b , The outstanding endface 134c is an area that is essentially parallel to the end face 132a is and is in the axial direction X at the front end of the outer cylinder 130 located. The fitting part 126 forms the step between the end face 132a and the outstanding endface 134c ,

As in 10 etc. is the stator 120 manufactured in a state in which the Einpassteil 126 in the sealing part 146 is fitted. In particular, the stator main body is 142 for the stator 120 on the outer cylinder 130 so molded that a mold is created in which the Einpassteil 126 in a radial intermediate position of the sealing part 146 is fitted. In addition, located in the stator 120 a peripheral surface 146c of the sealing part 146 opposite the position where the fitting part 126 is provided, radially outside the outer cylinder 130 ,

Next, a deformation control of the seal parts 146 and 147 of the stator 120 described. Note that the seal part 146 in the following description of this embodiment will be described and a description of the sealing part 147 is omitted because the seal parts 146 and 147 have similar structures.

Similar to the stator 20 the first embodiment, the sealing part 146 between the outer cylinder end 132 and the end connector 13 jammed when the stator 120 on the uniaxial progressing cavity pump 10 is attached, and thus comes into a state in which it is from both sides in the axial direction X is pressed. The sealing part 146 tends to stretch elastically radially to the outside of the stator 120 deform by moving the compressive force from both sides in the axial direction X receives.

Here shows the fitting part 126 this embodiment an anchoring function at a radial intermediate position of the sealing part 146 , In particular, the fitting part restricts 126 a diameter increase of the sealing part 146 one that is inside the inner wall surface 134a is arranged. So the stator 120 check or prevent the gluing of the fastening area 124 releases by reducing the tension on the mounting area 124 acts in which the sealing part 146 and the outer cylinder end 132 stick to each other. In addition, the stator limits 120 the elastic deformation radially to the inside of the sealing part 146 through the outside wall surface 134b when it comes from the uniaxial progressing cavity pump 10 Will get removed.

Thus, the stator is limited 120 the elastic deformation of the sealing part 146 when attaching and removing to / from the single-axis eccentric screw pump 10 is to be expected. In addition, the stator limited 120 the elastic deformation of the sealing part 146 to the stress of the mounting area 124 decrease and the detachment of the outer cylinder 130 and the stator main body 142 to prevent. Consequently, damage to the stator 120 controlled or avoided.

In addition, the stator 120 in addition to the end face 132a and the outstanding end face 134c the entire inner wall surface 134a and outer wall surface 134b or part of it as a mounting surface 124 use. That is, the stator 120 can the gluing area of the stator main body 142 and the outer cylinder end 132 around the area of the inner wall surface 134a and the outer wall surface 134b expand the peripheral surfaces (side surfaces) of the fitting 126 form. Thus, compared to the conventional stator 520 the adhesive power of the sealing part 146 and the outer cylinder end 132 improved, and a detachment of the sealing part 146 from the outer cylinder end 132 can be prevented.

Third Embodiment

Next is a stator 220 according to a third embodiment of the present invention. Note that in the following description, structures similar to those in the stator 20 are described using the same reference numerals in order to avoid a detailed explanation.

As in 11 is shown, the stator 220 an outer cylinder 230 and a stator main body 242 on. The stator main body 242 has flange-shaped sealing parts at both ends 246 and 247 on. In addition, similar to the stator 20 the first embodiment also in the stator 220 the outer cylinder 230 and the stator main body 242 formed technically in one piece, for example by pouring the molding material of the stator main body 242 in the outer cylinder 230 to which adhesives adhere.

The stator 220 has at both ends in the axial direction X stator ends 222 and 223 on. fixing areas 224 and 225 are at the stator ends 222 respectively. 223 intended. In addition, the outer cylinder has 230 Outer cylinder ends (ends) 232 and 233 at both ends in the axial direction X , The stator 220 has the attachment areas 224 and 225 each in contact parts of the outer cylinder ends 232 and 233 with the sealing parts 246 respectively. 247 on. The stator 220 is by fixing the outer cylinder ends 232 and 233 and the sealing parts 246 and 247 by adhesives, etc. in the attachment areas 224 respectively. 225 educated.

The stator 220 has at both ends in the axial direction X fitting portions 226 and 227 on. The stator 220 has the Einpassteil 226 and the attachment area 224 at the end of the stator 222 on and has the Einpassteil 227 and the attachment area at the stator end 223 on. Note that in the description of this embodiment, the description of the fitting part 227 , the outer cylinder end 233 , the sealing part 247 and the attachment area 225 is omitted.

As in 11 is shown is the Einpassteil 226 a concave / convex part at the outer cylinder end 232 is trained. More specifically, the Einpassteil points 226 a concave part 236 and a convex part 238 on, at the outer cylinder end 232 are formed. The fitting part 226 forms through the combination of the concave part 235 respectively. 236 and the convex part 238 Steps in the outer cylinder end 232 , The concave part 236 is formed as a substantially circular recess extending from the end surface 232a is pressed in. The convex part 238 is formed as an annular projecting part, which in the axial direction X protrudes. In addition, the convex part 238 radially inside the concave part 236 educated. In addition, the Einpassteil 226 provided at a position away from the peripheral edge 232b the endface 232a offset radially inward. The fitting part 226 is designed to be to the peripheral edge 232b the endface 232a fits.

In the stator 220 is the sealing part 246 brought into a fitting shape (concave-convex shape) that matches the shapes of the concave part 235 respectively. 236 and the convex part 238 fits. More specifically, the sealing part 246 Made in a convex shape that is in the axial direction X towards the outer cylinder end 232 protrudes at a position that is to the concave part 235 fits. In addition, the sealing part 246 Made in a concave shape that is in the axial direction X is pressed in at a position that is to the convex part 238 fits. Thus the stator 220 Made in such a shape that the concave-convex parts (the fitting part) of the outer cylinder end 232 and the sealing part 246 in the axial direction X fit together in the part in which the fitting part 226 located.

To the Einpassteil 226 as in 11 shown to describe in more detail, the Einpassteil 226 , a plurality of side surfaces (peripheral surfaces) that form the concavo-convex shape. In particular has the Einpassteil 226 a first wall surface 234a as inner peripheral surface, which is the concave section 236 forms. In addition, the Einpassteil has 226 a second wall surface 234b on the outer peripheral side and a third wall surface 234c on the outer peripheral side than the side surfaces (peripheral surfaces) which are the convex part 238 form. The first wall surface 234a and the third wall surface 234c are formed as side surfaces of the outer cylinder 230 pointing radially inwards. In addition, the second wall surface 234b formed as a side surface of the outer cylinder 230 pointing radially outwards.

In addition, the Einpassteil points 226 a first floor area 234d , an upper surface 234e and a second floor surface 234f as surfaces on, which are substantially parallel to the end surface 232a are. The first floor area 234d is between the first wall surface 234a and the second wall surface 234b educated. The top 234e is between the second wall surface 234b and the third wall surface 234c educated. The second floor area 234f is inside the third wall surface 234c educated. The fitting part 226 forms steps between the end surface 232a on the one hand and the first floor surface 234d and the second floor area 234f on the other hand.

As in 11 is shown, is the concave part 236 within the first wall surface 234a educated. There is also a reception area 240 in the concave part 236 educated. The recording area 240 can be a part of the sealing part 246 in the axial direction X take up. In a state where the stator main body 242 to the outer cylinder 230 is molded, the seal part 246 in a state in which the entire area in the radial direction except for the part in the axial direction X in the recording area 240 is included. In addition, the convex part comes 238 in a state in which it is in the axial direction relative to the sealing part 246 that is in the reception area 240 is included. Thus, the stator 220 constructed so that the outer cylinder end 232 and the sealing part 246 are mounted together in the state in which the stator main body 242 in the outer cylinder 230 is poured.

If the stator 220 on the single-axis eccentric screw pump 10 is attached, the sealing part 246 between the outer cylinder end 232 and the end neck 13 trapped and enters a state in which it is from both sides in the axial direction X is pressed. The sealing part 246 tends to be radial to the outside of the stator 220 to deform elastically by the compressive force from both sides in the axial direction X receives. The stator 220 limits the radial elastic deformation of the sealing part 246 through the first wall surface 234a which the peripheral surface 246c of the sealing part 246 touched radially from the outside. In addition, the convex part 238 an anchoring function at a radial intermediate point of the sealing part 246 in the reception area 240 is housed. Thus, the stator limits 220 the radially outwardly and radially inwardly directed elastic deformations of the sealing part 246 at an intermediate point of the sealing part 246 while he the radially outwardly directed elastic deformation of the sealing part 246 limited. That is, the stator 220 causes the double limitation of the elastic deformation of the sealing part 246 , Thus, the stator 220 prevent the sealing part 246 due to the elastic deformation of the sealing part 246 from the outer cylinder end 232 replaces.

In addition, the stator 220 when forming the stator main body 242 on the outer cylinder 230 the first wall surface 234a , the second wall surface 234b and the third wall surface 234c than the attachment area 224 use, in addition to the first floor surface 234d , to the top surface 234e and to the second floor area 234f , That is, the stator 220 can the adhesive area of the sealing part 246 and the outer cylinder end 232 around the area of the first wall surface 234a , the second wall surface 234b and the third wall surface 234c expand that form the peripheral surface (side surface). So the stator 220 the adhesive or adhesive power between the sealing part 246 and outer cylinder end 232 improve to prevent the sealing part 246 from the outer cylinder end 232 replaces.

As described above, the stator of the present invention is not limited to these structures, although the first embodiment, the second embodiment, and the third embodiment of the present invention will be described and the mating parts of the stators 20 . 120 and 220 be described exactly.

Although the wall surface 34a with the shape extending in the axial direction X curved, described in the description of the first embodiment, and the inner wall surface 134a and the outer wall surface 134b along the axial direction X are formed to be described in the second embodiment, the shapes of the wall surfaces having the fitting part of the present invention are not limited to these constructions.

For example, as in 12 (a) shown, the wall surface that the stator of the present invention has, a wall surface 301 be designed so that it is substantially perpendicular to the bottom surface 34b instead of the wall surface 34a which is the curved surface of the first Embodiment. In addition, as in 12 (b) shown, the wall surface that the stator of the present invention has, a wall surface 302 instead of the wall surface 34a be, their shape to the axial directions X is inclined and which is designed so that it is at an obtuse angle to the floor surface 34b lies. Alternatively, the wall surface that the stator of the present invention has may be a wall surface 303 be designed so that it is at an acute angle to the floor surface 34b lies as in 12 (c) is shown.

Further, the wall surface having the stator of the present invention may be constructed to be a wall surface that is substantially perpendicular to the bottom surface, similar to that in FIG 12 (a) shown wall surface 301 , instead of the inner wall surface 134a and the outer wall surface 134b in the second embodiment, or may be configured to be a wall surface that is relative to the axial direction X curves. Further, the wall surface that the stator of the present invention has may be an area that is toward the axial direction X is inclined, or an area that is relative to the axial direction X curves, instead of the first wall surface 234a , the second wall surface 234b and the third wall surface 234c in the third embodiment. In any case, different shapes can be selected for the wall surface.

Although in the first embodiment, the stator 20 with the fitting part 26 is described with the concave shape (concave part) brought into the circular-depressed shape, the stator of the present invention is not limited to this structure. For example, the stator of the present invention may be a fitting part 312 be in an annular groove like in the 13 (a-1) and (a-2) is incorporated.

As in the 13 (b-1) and (b-2), the stator of the present invention may also be constructed such that a stator main body 322 on the outer cylinder described in the second embodiment 130 is cast on. In particular, the stator of the present invention can be constructed such that the stator main body 322 to the outer cylinder 130 is cast on, so that the sealing part 324 radial in the fitting 126 (convex section) is included.

Although the description of each embodiment of the stator of the invention described above describes the fitting part with a concave part or a convex part or both the concave part and the convex part, the present invention is not limited to this structure.

For example, the stator of the present invention may include a fitting part having two convex portions, such as one in FIG 14 (a) illustrated stator 330 , Moreover, the stator of the present invention may include a fitting part having a convex portion and a concave portion such as in FIG 14 (b) illustrated stator 340 , Further, the stator of the present invention may have a fitting part having two convex portions, such as in FIG 14 (c) illustrated stator 350 , Alternatively, the stator of the present invention may include two wall surfaces formed to be axial X tend, and have a Einpassteil that does not form the stepped shape, such as in 14 (d) illustrated stator 360 ,

In any case, the fitting part of the stator of the present invention can have any shape as long as it has such a shape that the outer cylinder and the stator main body are fitted into each other.

Although in each embodiment of the stator of the present invention described above, the outer cylinders 30 . 130 and 230 described having the circular cross-section, and the stators 20 . 120 and 220 which the fitting parts 26 . 134 and 234 comprising the circular or annular concave part or convex part, the outer cylinder and the fitting part belonging to the stator of the present invention are not limited to these structures.

For example, as in 15 (a) illustrated, the stator of the present invention, a fitting 372 formed in the concave portion or the convex portion having a ring shape, a part of which is divided along the outer edge of the outer cylinder end. Alternatively, the stator of the present invention may include a fitting part which is fitable in the annular concave part or the convex part, which are formed partially along the outer edge of the outer cylinder end. In addition, as in 15 (b) illustrated, the stator of the present invention, a fitting 374 which is formed in a recess or a convex part having a polygonal shape formed along the outer edge of the outer cylinder end. Furthermore, as in 15 (c) That is, the stator of the present invention, when the outer cylinder and the stator main body have the oval cross-sectional shape, a Einpassteil 376 which is formed along the outer edge of the outer cylinder end in an oval recess or a convex portion. When the outer cylinder has the circular cross section and the stator main body has the polygonal shape, such as is substantially triangular in shape, the stator of the present invention may be suitably selected from a fitting part made in a shape matching the shape of the seal member formed in the stator main body.

In addition, the stator of the present invention, the Einpassteil at one of the two ends in the axial direction X respectively. In addition, the stator of the present invention may include mating parts that extend axially at both ends X have different shapes. For example, in the stator of the present invention, the fitting part in either end may be the concave part, and the fitting part in the other end may be the convex part.

In addition, in the stator of the present invention, the materials of the outer cylinder and the stator main body can be made according to the type, property, etc. of the pumping object or fluid that is used with the uniaxial progressing cavity pump 10 object to be funded is selected appropriately.

[Industrial Applicability]

The stator of the present invention may suitably be used for the single-eccentric screw pump or an applicator using the single-axis eccentric screw pump.

LIST OF REFERENCE NUMBERS

10

Uniaxial progressing cavity pump

20

stator

24, 25

fastening area

26, 27

Fitting part (concave part)

32, 33

Outer cylinder end part (end part of the outer cylinder)

34a, 35a

wall surface

36, 37

reception area

42

stator main

42a

Inner circumferential surface

46, 47

sealing part

46c

peripheral surface

48

insertion

50

rotor

120

stator

122, 123

stator end

124, 125

fastening area

126, 127

Fitting part (convex part)

132, 133

Outer cylinder end part (end part of the outer cylinder)

142

stator main

146, 147

sealing part

146c

peripheral surface

220

stator

224, 225

fastening area

226, 227

Fitting part (concave part, convex part)

230

outer cylinder

232, 233

Outer cylinder end part (end part of the outer cylinder)

234a

first wall surface (wall surface)

234b

second wall surface (wall surface)

234c

third wall surface (wall surface)

236

Concave part

238

Convex part

240

reception area

242

stator main

246, 247

sealing part

246c

peripheral surface

301, 302,

303 wall surface

310

stator

312

fitting part

322

stator main

324

sealing part

330

stator

340

stator

350

stator

360

stator

372

fitting part

374

fitting part

376

fitting part

X

axially

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• JP 2004360469 A [0004]

Claims (10)

Stator of a single-axis eccentric screw pump, which is constructed so that an externally threaded rotor is rotatably inserted into an internally threaded insertion hole of the stator, and an object to be conveyed is conveyed by the rotor is eccentrically rotated via a drive source, comprising: a stator main body formed of elastomer and having in its inner peripheral surface the female threaded insertion hole extending in the axial direction of the stator; and an outer cylinder, which is externally attached to the stator main body, wherein the stator main body has a flange-shaped sealing part at at least one end, the stator having a mounting area to which the sealing part and the outer cylinder stick, wherein the outer cylinder and / or the sealing part have a fitting part which protrudes or is pressed in the axial direction of the stator, wherein the fitting part is formed so that at least a part of the outer cylinder and the sealing part is fitted in the other, and wherein the fitting part and the fixing portion are provided on at least one of the both ends of the stator and prevent deformation of at least a part of the sealing part due to a pressing of the stator in the axial direction. Stator after Claim 1 having a wall surface forming a side surface of the fitting part provided at the end of the outer cylinder. wherein the wall surface restricts the deformation in at least a part of the sealing part in a direction that intersects the axial direction of the stator. Stator after Claim 1 or 2 , with a wall surface forming a side surface of the fitting part provided at the end of the outer cylinder. wherein the entire wall surface or a part thereof is shaped so that it fits all or part of the contour of the peripheral surface of the sealing part. Stator after one of the Claims 1 to 3 , with a wall surface forming a side surface of the fitting part provided at the end of the outer cylinder. wherein the entire wall surface or a part thereof is arranged so that it faces at least a part of the peripheral surface of the sealing part. Stator according to one of the Claims 1 to 4 , with a wall surface that forms a side surface of the fitting provided at the end of the outer cylinder. wherein all or part of the wall surface is arranged so as to surround the peripheral surface of the sealing part. Stator according to one of the Claims 1 to 5 , comprising: a wall surface forming a side surface of the fitting part provided at the end of the outer cylinder; and a receiving portion constructed in the wall surface, all or part of the wall surface being arranged to surround the peripheral surface of the sealing member, and the sealing member having a portion received in the receiving portion, and a part extending in the axial direction of the Stator protrudes from the recording area. Stator according to one of the Claims 1 to 6 , wherein the fitting part provided at the end of the outer cylinder is the outer cylinder end which has a step in the axial direction of the stator. Stator according to one of the Claims 1 to 7 , wherein the fitting part provided at the end of the outer cylinder is formed with one or both of a concave portion that is shaped in a concave shape in the axial direction of the stator and a convex portion that is shaped in a convex shape. Stator after one of the Claims 1 to 8th , wherein the sealing part and the outer cylinder are fixed by gluing with adhesives or by hot pressing. Single-axis eccentric screw pump with the stator after one of the Claims 1 to 9 ,

Images